THE ORIGIN OF PURINES IN PLANTS.2

THE

ORIGIN OF PURINES I N

PLANTS.

33 7

kept in a desiccator until used. All the determinations were carried out in an atmosphere of dry nitrogen. The apparatus used was similar to that described by Zerewitinoff, and the magnesium methyl iodide was prepared in accordance with his directions. No attempt was made to explain the results given in the above table, which differ so strikingly from those obtained by Zerewitinoff. It is certain, however, that the pyridine used was of a higher grade of purity than the technical pyridine which he used, and it was a t least as dry. The fact that Oddo' obtained satisfactory results by its use may be due to the fact that he employed magnesium ethyl iodide. In conclusion, attempts to utilize pyridine as a solvent in accordance with Zerewitinoff's directions have failed completely from a quantitative point of view, not only with the technical product but with the repurified Kahlbaum material. Even with added precautions, pyridine has not been found to be a suitable solvent for use in this method; and it would therefore seems advisable that this method be subjected to further investigation before results obtained by its use are accepted. The author wishes to acknowledge his indebtedness to H. Hibbert, a t whose suggestion this work was undertaken. SWARTHlfOR8 COLLSQS,

SWARTEXORE, PA.

[CONTRIBUTIONS FROM

THE

SHEFFIELD CHEMICAL LABORATORY OF YALEUNIVERSITY. ]

THE ORIGIN OF PURINES IN PLANTS.2 BY T R 8 A T

B. JOHNSON.

Received November 24, 1913.

In the plant kingdom purines occur as normal constituents of the plant cell, linked to sugar in the nucleic acids, and also in a free condition as stable end products of the metabolism of nitrogen. They are found in certain plants associated with protein in all the organs, apparently, in which protein is synthesized or utilized in plant growth. Regarding the mechanism of the processes of formation, or the chemical nature of the simpler organic compounds,which participate in their syntheses, we have, however, practically no knowledge. The primary object of this paper is to present some interesting data, which are very suggestive of the mechanism of purine formation, and which have led us to undertake some new investigations in this fruitful field. Every process, which has been applied successfully in the labmatory, for the synthesis of purine compounds, is based upon the general principle that the imidazole ring can be introduced into the pyrimidine nucleus. 1

Ber., 4, 2040 (1911). Pyrimidine Paper LXV.

TREAT R. JOHNSON

338 N-C

N-C

I

!

I

’

c c

--+-

+ C-N ’ / Imidazole

N-C Pyrimidine.

‘

I

Purine

This has been effected in different well known ways and it is not necessary to discuss these methods here. The only exception to this general procedure is apparently the observation of Horbaczewski‘ that uric acid is formed in small amount by fusion of urea with aminoacetic acid or the amide of trichlorolactic acid. Gautier,2in 1884, claimed to have obtained the purines, xanthine and methylxanthine, by heating hydrocyanic acid with acetic acid and water and expressed the transformation according to the following equation: IIHCN 4Hz0 = C5H402X4 CsH602Na.

+

+

Xanthine

Methylxmthine

Gautier’s products showed a long series of precipitation and color reactions also given by xanthine. This work of Gautier’s was repeated, thirteen years later, by Emil F i ~ c h e r who , ~ showed that the products obtained by Gautier did not give the murexide test and consequently he concluded that they could not be purine compounds. During the following year Gautier4 replied to Fischer’s paper and again discussed the several reactions of his products, which were characteristic of xanthine. He contributed, however, no new experimental evidence to support his conclusions, and, so far as the writer is aware, no further work of Gautier or other investigators, confirming these observations, has since been published. The reverse process of purine formation, namely, that involving their synthesis from imidazoles or hydantoins by incorporation of the pyrimidine urea nucleus has, so far as the writer is aware, never been accomplished. Attempts to effect such transformations, which have been made in this laboratory,$ have so far proved unsuccessful. It is of interest to note in this connection that Latham’s theory of the formation of uric acid in the animal body is based on the ground, that this purine results by synthesis through the stages of hydantoin and biuret. Uric acid, however, has never been detected in plants, and it has not been definitely established that hydantoin is a naturally occurring compound. The only evidence that hydantoin may occur in plants, which the writer has been able to find, is that given in a paper by Lippmann6 who writes as follows: “doch 2

Rer , IS, 2678; Monatsh , 6 , 3 5 6 , 8, Compt rend , 98, 1.521

17npuhlishedwork Bel’, 29, 2 6 5 2

202

339

THE ORIGIN OF PURINES IN PLANTS.

sei bei dieser Gelegenheit erwahnt, dass Hydantoin einmal aus dem Safte der bleichen Schosslinge erhalten wurde, die bei feuchtwarmem Wetter in oft erstaunlicher Lange durch das sogenannte ‘ Auswachsen ’ der Ruben in den Mieten entstehen und reich an stickstoffhaltigen Verbindungen vershiedener Natur sind. Es bildete kleine weisse Krystalle, deren Schmelzpunkt, der wegen vorherigen Sinterns schwer genau festzustellen ist, bei 214’lag, loste sich leicht in heissem Wasser, besass die Zusammensetzung C ~ H ~ O Z(gef. N Z 35.85 p. ct. C, 4.17 p. ct. H, 27.88 p. ct. N, 3 2 . 1 0 p. ct. 0; ber. 36.00 p. ct. C, 4.00 p. ct. H, 28.00 p. ct. N, 32.00 p. ct. 0) und gab mit ammoniakalischem Silbernitrat eine mikrokrystallinische Silberverbindung C3H3O2N2Ag HzO.” Whether this interesting compound results from the decomposition of allantoin, which has been shown to occur in plants, or is formed by direct synthesis from glycocoll, or is produced by the oxidation of purine compounds, we have no knowledge. The important fact that purine can be so easily synthesized from pyrimidine compounds is a very strong argument, from a chemical standpoint, that representatives of the latter class of compounds are probably the precursors of purines in plant growth. Several investigators have called attention to this genetic relationship and have suggested that cytosine, I, and uracil, 11, may be the two pyrimidines involved in these changes. The close structural relationship between these two pyrimidines and the purines, adenine, 111, and xanthine, IV, respectively, for example,

+

N = CNH2

I / CO CH I /I

NH-CH

I.

NH-CO

I

CO

I

/ CH 11

NH-CH 11.

N = CNH2

1 1 CH C-NH 1/11 N-C

-N 111.

NH-CO

>,,

I

CO

1

/

C-NH

11

NH-C IV.

-N

)CH

is surely very suggestive, but notwithstanding this fact, it seems very safe to assume that this relationship will never be of more than theoretical interest, until new methods of converting these two pyrimidines into purines have been developed. Admitting that it is possible to convert pyrimidines of this type into purines,2yet, no method has been developed by which purines can be obtained from uracil and cytosine, which still retain the original CO or C-NHz pyrimidine groupings in the 6-position of the purine nucleus. These two groupings are characteristic of all the naturally occurring purines. The 3-carbon chain is likewise a characteristic grouping in all naturally occurring purines, and also pyrimidines with the exception of thymine, which contains a methyl group in the

12,

Z . Rubenz. Ind., 35, 159. 2Johns, A m . Chem. Jour., 41, 59; 45, 79; J . Biol. Chem., 9, 161;11, 67, 73, 393; 91; 14, 1, 299; 15, 119, 515; 16, 135.

TREAT B. JOHNSON.

340

N = C.NH2

N-CQ

I I

7

I 1

C-Yc

N-C-N" 1'.

/ VI

g -position of the pyrimidine ring.

This pyrimidine, therefore, occupies an anomalous position. It is possible that plant enzymes may be found, which are capable of oxidizing uracil and cytosine to isodialuric and aminoisodialuric acids, respectively, but no such transformation has yet been effected in the laboratory by direct oxidation. Wheeler and Johnson1 have shown that both uracil and cytosine can be converted into isodiaiuric acid, VIII, but the change involves, first, the formation of the dibromopyrimidine VII, by the action of hypobromous acid and secondly a treatment with alkali to remove the two halogen atoms. The transformation of uracil is represented by the following formulas : NH-CO

NH-CO

!

00 I

'

I

CH t

II

NH-CH

+

I

I

CO C